ITBO20100183A1 - SOLAR ENERGY SYSTEM FOR HEATING WATER HEAT - Google Patents

Description

DESCRIPTION

â € œSOLAR ENERGY SYSTEM FOR SANITARY WATER HEATINGâ €

The present invention relates to a solar energy system for heating sanitary water.

In particular, the present invention relates to a solar energy system of the type comprising a solar collector for heating a thermovector fluid and a heat exchanger crossed by the thermo-vector fluid and sanitary water to be heated.

It is known that in a solar energy system of the type described above, the exchanger is defined by a cylindrical tank of considerable size and such as to be able to accumulate a quantity of sanitary water sufficient to supply domestic users.

A system of the type described above has the disadvantage that the relevant dimensions and the cylindrical shape of the tank generate a localized load on the roof such as to be able to damage the roof itself. Furthermore, the size and shape of the tank cause strong wind resistance and snow accumulation, with the consequent risk of damage to both the roof and the solar energy system.

The purpose of the present invention is to provide a solar energy system for heating sanitary water, which allows to eliminate the drawbacks described above.

According to the present invention there is provided a solar energy system for heating sanitary water according to what is disclosed in claim 1 and, preferably, in any of the subsequent claims directly or indirectly dependent on claim 1.

The invention will now be described with reference to the attached drawings, which illustrate non-limiting examples of implementation, in which:

Figure 1 is a perspective view of a preferred embodiment of the solar energy system of the present invention;

Figure 2 illustrates an exploded view of a first embodiment of the solar energy system according to the present invention;

- figure 3 is a section, on an enlarged scale, along the line III-III of a detail of figure 2; Figure 4 illustrates an exploded view of a second embodiment of the solar energy system according to the present invention;

- figure 5 is a section, on an enlarged scale, along the line V-V of a detail of figure 4;

Figure 6 illustrates an exploded view of a third embodiment of the solar energy system according to the present invention; And

Figure 7 illustrates, on an enlarged scale, a detail of Figure 6.

In figure 1, 1 indicates as a whole a solar energy system for heating sanitary water comprising a solar collector 2 for heating a thermo-vector fluid, a heat exchanger 3 for heating sanitary water, a circuit 4 for supplying sanitary water to the exchanger 3 and a circuit 5 for the circulation of the thermo-vector fluid, which is of a known type and comprises, for example, a mixture of water and glycol.

According to what is illustrated in figures 2, 4 and 6, the exchanger 3 comprises a box-like body 6 having a plurality of housings 7, which house respective accumulation units 8 fluidically connected to each other, as will be explained better below. There are three storage units 8. The box-like body 6 has a pair of side surfaces of larger plane dimensions, one in contact with a support surface and one opposite which delimits the maximum overall dimensions of the exchanger 3 at the top.

The storage units 8 have along an axis H, perpendicular to the support surface of the roof, a footprint smaller than the maximum footprint of the collector 2 along the same axis H.

According to what is illustrated in Figure 1, the box-like body 6 has a size along the axis H equivalent to the maximum size of the manifold 2 along the axis H itself.

The domestic water supply circuit 4 and the thermo-vector fluid supply circuit 5 are arranged in countercurrent.

According to the first embodiment of the solar energy system 1 illustrated in Figures 2 and 3, each storage unit 8a is defined by a hollow body 9a, which has a longitudinal axis 10a, and comprises a coil 11a for the passage of the fluid thermo-vector and a 12a circulation system of sanitary water. The serpentine 11a is arranged, at least partially, inside the body 9a.

The circulation system 12a comprises an inlet conduit 14a and an outlet conduit 13a for sanitary water, which pass through the same wall of the storage unit 8a. The inlet conduit 14a has a length such as to prevent mixing between the water entering and leaving the storage unit 8a; in particular, the inlet conduit 14a extends along the axis 10a for a portion greater than half the length of the body 9a.

It can be observed that the circuit 5a for the heat carrier fluid comprises a delivery duct 15a which is arranged at the outlet from the manifold 2a for feeding the hot thermo-carrier fluid to the exchanger 3a. The coils 11a of a pair of adjacent storage units 8a are connected in parallel to the external conduit 15a. The circulation systems 12a of a pair of adjacent storage units 8a are connected in series to each other.

In the second embodiment illustrated in Figures 4 and 5, each storage unit 8b is defined by a hollow body 9b, which has a longitudinal axis 10b, and comprises a sanitary water circulation system 12b.

The circulation system 12b comprises an inlet conduit 14b and an outlet conduit 13b for sanitary water, which pass through the same wall of the storage unit 8b. The inlet duct 13b has a length such as to prevent mixing between the water entering and leaving the storage unit 8b; in particular, the inlet conduit 14b extends along the axis 10b for a portion greater than half the length of the hollow body 9b. The circulation systems 12b of a pair of adjacent storage units 8b are connected in series.

The circuit 5b for the thermo-vector fluid comprises a delivery duct 15b which is arranged at the outlet from the manifold 2b for feeding the hot thermo-vector fluid to the exchanger 3b.

The exchanger 3b comprises a jacket 21b, which is arranged around each storage unit 8b and is traversed internally by the thermo-vector fluid. The lining 21b defines around each storage unit 8b a chamber 16b crossed by the heat-carrying fluid.

As shown in figure 4, the lining 21b houses the storage units 8b and the thermo-vector fluid flows inside a chamber 16b (figure 5) bounded, externally, by the lining 21b and, internally, by the bodies 9b of the storage unit 8b.

The distance between the lining 21b and each body 9b is such as to produce a laminar motion of the heat transfer fluid over the entire longitudinal extension of each storage unit 8b.

Both the first embodiment and the second embodiment relate to a solar energy system 1a (1b) with natural circulation, in which the motion of the thermo-vector fluid and of the sanitary water is given by the convective motion generated by the heat solar.

According to the third embodiment, illustrated in Figure 6, the solar energy system 1c comprises a recirculation unit R comprising, in turn, a photovoltaic device 17c and an electric circulator 18c powered by the photovoltaic device 17c itself. Preferably, the photovoltaic device 17c comprises a solar panel.

According to what is illustrated in Figure 7, the circulator 18c comprises an electric cable 19c for connection with the photovoltaic device 17c and is arranged so as to regulate the flow inside the circuit 5c for the circulation of the thermo-vector fluid.

According to the third embodiment illustrated in Figure 6, the solar energy system 1c comprises an exchanger 3c similar to that illustrated in Figures 2 and 3 for the first embodiment.

According to a further embodiment, not shown, the solar energy system 1 comprises an exchanger 3 of the type illustrated in Figures 4 and 5 for the second embodiment and also comprises a recirculation unit R.

According to a further variant, not shown, the circulator 18 is arranged so as to regulate the flow inside the water supply circuit 4.

Finally, according to what is illustrated in Figures 1, 2, 4 and 6, the solar energy system 1 comprises a plurality of protective walls 20, which are suitable for enclosing the group formed by the collector 2, the exchanger 3, the circuit 4 of sanitary water supply and the circuit 5 for the supply of heat transfer fluid.

In use, the heat developed by the sun's rays in the collector 2 activates the circulation of the heat transfer fluid through circuit 5.

The hot thermo-vector fluid is sent to the exchanger 3, where it is used to heat the sanitary water. As illustrated in figures 2, 4 and 6, the thermo-vector fluid progressively heats the storage units 8 by passing through the exchanger 3 from an storage unit 8 at a lower temperature to an accumulation unit 8 at a higher temperature .

It follows from the foregoing that a solar energy system 1 according to the present invention has reduced overall dimensions while ensuring a sufficient quantity of heated water to supply domestic users.

Furthermore, the small size of each storage unit 8 contained inside the box-like body 6 gives the exchanger 3 of the solar energy system 1 a flattened shape. The solar energy system 1 extends, once mounted, substantially parallel to the roof (figure 1), reducing the overall dimensions and avoiding damage due to the accumulation of snow or wind. Finally, the box-like body 6 with a flat and extended supporting wall and the plurality of storage units 8 placed side by side allows the load of the solar energy system 1 to be redistributed over a larger area of the roof, considerably reducing the risk of damage.

Claims (8)

CLAIMS 1. Solar energy system for heating sanitary water comprising a solar collector (2) for heating a thermo-vector fluid, a heat exchanger (3) for heating sanitary water, a supply circuit (4) sanitary water to the heat exchanger (3) and a thermo-vector fluid supply circuit (5), which is designed to exchange heat both with the manifold (2) and with the exchanger (3); the solar energy system being characterized in that the heat exchanger (3) comprises a plurality of storage units (8); and that the size of each storage unit (8) along an axis (H) perpendicular to a support base of the solar energy system (1) is less than the maximum size of the collector (2) along the said axis (H). 2. Solar energy system according to claim 1, wherein each storage unit (8) comprises a hollow body (9) and a sanitary water circulation system (12); wherein the sanitary water circulation system (12) comprises an inlet conduit (14) which flows into the body (9) and an outlet conduit (13); wherein the inlet conduit (14) and the outlet conduit (13) cross a same wall of the hollow body (9); and in which the body (9) has a longitudinal axis (10) and the inlet duct (14) extends inside the body (9) for a length greater than half the longitudinal extension of said body (9 ). Solar energy system according to claim 2, wherein the sanitary water circulation systems (12) of a pair of adjacent storage units (8) are connected in series. 4. Solar energy system according to one or more of the preceding claims, in which the exchanger (3) comprises a box-like body (6), in which the storage units (8) are housed. 5. Solar energy system according to one of the preceding claims, wherein the thermo-vector fluid supply circuit (5a; 5c) comprises a plurality of heat exchange elements (11a; 11c), each of which is arranged at least partially at the € ™ interior of a hollow body (9a; 9c) of a respective storage unit (8a; 8c). 6. Solar energy system according to claim 5 and comprising a delivery duct (15a; 15c) for the thermo-vector fluid arranged at the outlet from the collector (2a; 2c); the heat exchange elements (11a; 11c) of a pair of adjacent storage units (8a; 8c) are connected in parallel to the delivery duct (15a; 15c). Solar energy system according to one of claims 1 to 4, wherein the exchanger (3b) comprises a jacket (21b), which is arranged around each storage unit (8b) and delimits around the body (9b) of each storage unit (8b) a chamber (16b) crossed by the thermo-vector fluid leaving the manifold (2b); the chamber (16b) being able to exchange heat with each storage unit (8b). 8. Solar energy system according to one of the preceding claims and comprising a photovoltaic device (17c) and an electric circulator (18c), which is powered by said photovoltaic device (17c) for regulating the flow of a fluid inside of a respective circuit (4c; 5c).